Micromechanical Modeling of Tensile Behavior of Short Fiber Composites

A simple micromechanical constitutive model is developed for short fiber reinforced composites (SFRC) undergoing damage. The model is based on the Carman and Reifsnider approach for the prediction of mechanical properties of discontinuous fiber reinforced composites. The composite is modeled by a di...

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Veröffentlicht in:	Journal of composite materials 2002-02, Vol.36 (4), p.423-441
Hauptverfasser:	Meddad, Abderrahmane, Azaiez, Jalel, Ait-Kadi, Abdellatif, Guenette, Robert
Format:	Artikel
Sprache:	eng
Schlagworte:	Applied sciences Composite materials Composites Exact sciences and technology Experiments Fibers Forms of application and semi-finished materials Fracture mechanics (crack, fatigue, damage...) Fracture mechanics, fatigue and cracks Fundamental areas of phenomenology (including applications) Mathematical models Mechanics Micromachining Physics Polymer industry, paints, wood Solid mechanics Structural and continuum mechanics Technology of polymers
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container_title	Journal of composite materials
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creator	Meddad, Abderrahmane Azaiez, Jalel Ait-Kadi, Abdellatif Guenette, Robert
description	A simple micromechanical constitutive model is developed for short fiber reinforced composites (SFRC) undergoing damage. The model is based on the Carman and Reifsnider approach for the prediction of mechanical properties of discontinuous fiber reinforced composites. The composite is modeled by a distributed representative element composed of concentric circular cylinders using a general 3D configuration. The micromechanical model is used to evaluate the elastic properties of SFRC, by varying the orientation distribution of the fiber, the length distribution of the fiber and the fiber–fiber interaction phenomena. The composite is assumed to behave as linearly elastic in absence of any debonding of fiber from the matrix and in the fully debonded stage. The stress–strain behavior of molded composite materials and the debonding are modeled using the Hsueh model to estimate the debonding stress for misaligned fibers. A good agreement between calculated and experimental data was achieved.
doi_str_mv	10.1177/0021998302036004547
format	Article
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The model is based on the Carman and Reifsnider approach for the prediction of mechanical properties of discontinuous fiber reinforced composites. The composite is modeled by a distributed representative element composed of concentric circular cylinders using a general 3D configuration. The micromechanical model is used to evaluate the elastic properties of SFRC, by varying the orientation distribution of the fiber, the length distribution of the fiber and the fiber–fiber interaction phenomena. The composite is assumed to behave as linearly elastic in absence of any debonding of fiber from the matrix and in the fully debonded stage. The stress–strain behavior of molded composite materials and the debonding are modeled using the Hsueh model to estimate the debonding stress for misaligned fibers. 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The model is based on the Carman and Reifsnider approach for the prediction of mechanical properties of discontinuous fiber reinforced composites. The composite is modeled by a distributed representative element composed of concentric circular cylinders using a general 3D configuration. The micromechanical model is used to evaluate the elastic properties of SFRC, by varying the orientation distribution of the fiber, the length distribution of the fiber and the fiber–fiber interaction phenomena. The composite is assumed to behave as linearly elastic in absence of any debonding of fiber from the matrix and in the fully debonded stage. The stress–strain behavior of molded composite materials and the debonding are modeled using the Hsueh model to estimate the debonding stress for misaligned fibers. 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subjects	Applied sciences Composite materials Composites Exact sciences and technology Experiments Fibers Forms of application and semi-finished materials Fracture mechanics (crack, fatigue, damage...) Fracture mechanics, fatigue and cracks Fundamental areas of phenomenology (including applications) Mathematical models Mechanics Micromachining Physics Polymer industry, paints, wood Solid mechanics Structural and continuum mechanics Technology of polymers
title	Micromechanical Modeling of Tensile Behavior of Short Fiber Composites
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